Your search keyword '"Wang, Yechun"' showing total 34 results

1. Sulfoxide-containing polymers conjugated prodrug micelles with enhanced anticancer activity and reduced intestinal toxicity

Author

Wang, Yechun, Wang, Jiafeng, Li, JunJun, Mu, Yongli, Ying, Jiajia, Liu, Zimeng, Wu, Mengjie, Geng, Yu, Zhou, Xuefei, Zhou, Tianhua, Shen, Youqing, Sun, Leimin, Liu, Xiangrui, and Zhou, Quan

Published

2024

2. Experimental investigation on the separation characteristics of the novel combined separator

Author

Wang, Jinzhi, Wang, Yechun, Xie, Xiangdong, Xu, Qiang, Pan, Yingxiu, Wang, Gaoyun, and Guo, Liejin

Published

2024

3. Study on the synergistic effect of NaOH and CuSO4 in aquathermolysis upgrading

Author

Zhou, Yantao, Zhao, Qiuyang, Miao, Yan, Wang, Xuetao, Zhang, Yanlong, Wang, Yechun, and Guo, Liejin

Published

2023

4. Experimental investigation on hydrocarbon generation of organic-rich shale with low maturity in sub- and supercritical water

Author

Xie, Tian, Zhao, Qiuyang, Dong, Yu, Jin, Hui, Wang, Yechun, and Guo, Liejin

Published

2023

5. Investigation on separation characteristics of gas–liquid two-phase flow around the perforated tube

Author

Wang, Jinzhi, Wang, Yechun, Xie, Xiangdong, Xu, Qiang, Wang, Jiang, and Guo, Liejin

Published

2023

6. Centipeda minima: An update on its phytochemistry, pharmacology and safety

Author

Tan, Jincheng, Qiao, Zhiping, Meng, Mingjing, Zhang, Fan, Kwan, Hiu Yee, Zhong, Keying, Yang, Chunfang, Wang, Yechun, Zhang, Mi, Liu, Zhongqiu, and Su, Tao

Published

2022

7. Development and processing of novel heparin binding functionalized modified spider silk coating for catheter providing dual antimicrobial and anticoagulant properties

Author

Mulinti, Pranothi, Kalita, Deep, Hasan, Raquib, Quadir, Mohiuddin, Wang, Yechun, and Brooks, Amanda

Published

2020

8. A multiphase MPS solver for modeling multi-fluid interaction with free surface and its application in oil spill

Author

Duan, Guangtao, Chen, Bin, Zhang, Ximin, and Wang, Yechun

Published

2017

9. Investigations on bubble growth mechanism during photoelectrochemical and electrochemical conversions

Author

Wang, Yechun, Hu, Xiaowei, Cao, Zhenshan, and Guo, Liejin

Published

2016

10. Free-standing and mechanically flexible mats consisting of electrospun carbon nanofibers made from a natural product of alkali lignin as binder-free electrodes for high-performance supercapacitors

Author

Lai, Chuilin, Zhou, Zhengping, Zhang, Lifeng, Wang, Xiaoxu, Zhou, Qixin, Zhao, Yong, Wang, Yechun, Wu, Xiang-Fa, Zhu, Zhengtao, and Fong, Hao

Published

2014

11. Comparisons of clear coating degradation in NaCl solution and pure water

Author

Zhou, Qixin and Wang, Yechun

Published

2013

12. Impact of protein corona and PEGylation on the accumulation and efficacy of lysosome-disrupting lipid nanoparticles in KRAS-mutated cancer.

Author

Yang, Hang, Wang, Jiafeng, Zhou, Xinyi, Fu, Dongliang, Le, Chenqin, Wei, Jingsun, Qian, Yucheng, Fang, Yimin, Jin, Tian, Kong, Xiangxing, Yu, Chengxuan, Song, Dongjie, Wang, Yechun, Zhou, Xuefei, Zhou, Tianhua, Zhou, Quan, Liu, Xiangrui, Xiao, Qian, and Ding, Kefeng

Subjects

TARGETED drug delivery, NANOPARTICLES, POLYETHYLENE glycol, PROTEINS, PROTEOMICS

Abstract

Nanomedicines offer promising approaches for targeted drug delivery to tumor cells but their clinical translation is hindered by limited delivery efficacy in heterogenous clinical tumors. Protein corona adsorbed to the surface of nanoparticles (NPs) would cause opsonization and accelerate blood clearance, posing a significant barrier to effective drug delivery. Polyethylene glycol (PEG) modification is widely employed to prolong the NPs' circulation time and improve the delivery efficacy. Nevertheless, the clinical efficacy of PEG-based nanomedicines is still debatable. Here, we prepared non-PEGylated lysosomal-disrupting dimeric chloroquine (CQ) lipid nanoparticles (DCLNPs) and PEGylated DCLNPs (PEG-DCLNPs) and systematically studied the impact of PEGylation on DCLNPs' delivery efficacy in KRAS -mutant (MT) and -wildtype (WT) cancers. We found that the protein corona facilitates KRAS -MT cancer-specific targeted delivery of DCLNPs by exploiting extracellular protein engulfment preference. In contrast, PEGylation hindered delivery and efficacy of DCLNPs. Proteomics analysis highlighted apolipoproteins, particular apolipoprotein E, as key factors promoting the uptake of DCLNPs. Additionally, DCLNPs sensitized immunosuppressive KRAS -MT cancers to anti-PD1 immunotherapy. These results underscore the importance of comprehending the context-dependent role of the protein corona in regulating nanoparticle biodistribution, suggesting that PEGylation may not be suitable across all cancer types. [Display omitted] • Protein corona selectively promotes accumulation of DCLNPs in KRAS -MT cancer cells. • PEGylation of DCLNPs decreases accumulation and cytotoxicity in KRAS -MT cancers. • Proteomics analysis unveiles apolipoproteins critical for the accumulation of DCLNPs in KRAS -MT cancers. • DCLNPs remodeled the suppressive immune microenvironment of KRAS -MT cancers. [ABSTRACT FROM AUTHOR]

Published

2024

13. Insights into the hydrodynamic properties of slurry flow in a tubular photocatalytic reactor by PIV combined with LSIA.

Author

Geng, Jiafeng, Wang, Yechun, Hu, Xiaowei, and Jing, Dengwei

Subjects

*PHOTOCATALYSTS, *HYDRODYNAMICS, *TUBULAR reactors, *TURBULENT flow, *SUSPENSIONS (Chemistry), *ENERGY consumption

Abstract

Although turbulent flow is generally needed for good suspension of photocatalysts, lower flow rates are preferred from an economic viewpoint for energy-efficient operation. However, no experimental work has been conducted to reveal how photocatalyst particles move and distribute in a tubular photocatalytic reactor under mild operating conditions, which is critical for reactor design and configuration of the light concentration. In our study, the photocatalyst itself was employed as a tracer particle for Particle Image Velocity (PIV) measurement. PIV combined with a new laser sheet image analysis (LSIA) technology was employed to investigate both the particle velocity and number distribution in the tubular reactor. It was found that, in the inlet, a higher velocity distribution of fluid generally occurred in the lower part of the tube. However, in the middle and outlet regions of the tube, a higher velocity distribution existed in the upper part of the tube. LSIA investigation showed that the transport capacity of the fluid and the initial particle size distribution are two essential factors influencing particle number distribution in the suspension. Regardless of the particle size, the middle part of the reactor holds the maximum number of particles while the outlet has the minimum number of particles. In the inlet, both small and large particles show similar number distribution trends against the flow rate. However, in the middle part of the tube, the number of small particles decreases with the flow rate while the number of the large particles shows the opposite trend. The difference in velocity distribution along the radial direction also significantly affects the particle distribution. One interesting finding is that, regardless of the particle size, the number of particles in the upper part of the tube is always higher than that in centre. Stokes’ drag law and the Saffman lift force were employed to explain this experimental finding. In the last section, the correlation between particle distribution and optical properties was numerically investigated by a modified differential approximation (MDA) method. [ABSTRACT FROM AUTHOR]

Published

2016

14. Investigation and prediction of optical properties of alumina nanofluids with different aggregation properties.

Author

Song, Dongxing, Wang, Yechun, Jing, Dengwei, and Geng, Jiafeng

Subjects

*ALUMINUM oxide, *NANOFLUIDS, *CLUSTERING of particles, *LIGHT filters, *PARTICLE size distribution, *AGGLOMERATION (Materials), *OPTICAL properties

Abstract

Nanofluids as thermal absorption media or optical filters have showed great potential for application in direct absorption solar collector or hybrid photovoltaic/thermal (PV/T) collectors. Due to their nanoscale size and high surface energy, particles in nanofluid have a great tendency to aggregate into large secondary agglomerate, even in the presence of the anti-agglomeration agent, which could in turn lead to significant change in the thermal and optical properties of the nanofluid. However, rare work has been carried out to investigate the relation between the aggregation and optical properties of the nanofluid, which in our view, is of great importance for the enhanced performance of the nanofluid in solar collectors. In this study, taken alumina nanofluids with controlled particle aggregation properties as example, we were able to investigate the underlying correlation between the size distribution of the aggregate in nanofluid and their resulting absorption coefficients. It was found that inhibited aggregation and resultant smaller aggregated particle size could lead to larger absorption coefficient. Both Rayleigh scattering and Mie scattering theories have been attempted to predict the optical properties of the nanofluid after particle aggregation. The results indicate that values obtained by Rayleigh scattering theory are several orders higher than experimental values but that predicted by Mie scattering theory can reasonably match with the experimental results. Specially, it was demonstrated that by introducing the projected areas of the nanoparticle aggregate corresponding to smallest sphere enclosing diameter, more accurate absorption coefficient prediction based on Mie theory can be obtained. Our study is expected to provide a valuable guidance for the regulation of the optical properties of nanofluids and to improve their performance in solar collectors. [ABSTRACT FROM AUTHOR]

Published

2016

15. Flow accelerated degradation of organic clear coat: The effect of fluid shear.

Author

Zhou, Qixin, Wang, Yechun, and Bierwagen, Gordon P.

Subjects

*ORGANIC compounds, *METAL coating, *SHEAR (Mechanics), *CHEMICAL decomposition, *EPOXY compounds, *LAMINAR flow

Abstract

Flow accelerated organic coating degradation has been received attention, but the degradation mechanism is still not completely understood. In this study, we focus on investigating the influence of fluid shear on the degradation of organic coatings. A commercially available epoxy based clear coating was exposed to the laminar flow, and a 3.5 wt% NaCl solution was employed as the working fluid with a variety of flow rates. The change in the composition of the working fluid during the coating immersion was characterized by Fourier Transform Infrared Spectrometer (FTIR) and conductivity measurement. The effect of fluid shear is also demonstrated by the change in coating thickness. The barrier properties of organic coatings were monitored inline by Electrochemical Impedance Spectroscopy (EIS) measurement. The time evolution of coating resistance, capacitance, and permittivity obtained from the equivalent circuit model was studied to demonstrate the internal composition change of the coatings due to the flowing fluid. In this study, the experiments and analysis confirmed that flowing fluid promotes the release of coating materials from the coating into the surrounding working fluid while it accelerates the transport of water and ions into the coating. [ABSTRACT FROM AUTHOR]

Published

2014

16. Influence of the composition of working fluids on flow-accelerated organic coating degradation: Deionized water versus electrolyte solution

Author

Zhou, Qixin, Wang, Yechun, and Bierwagen, Gordon P.

Subjects

*ELECTROLYTE solutions, *WORKING fluids, *CORROSION & anti-corrosives, *PROTECTIVE coatings, *IMPEDANCE spectroscopy, *SOLUTION (Chemistry)

Abstract

Abstract: Corrosion protective coatings are known to degrade due to moisture exposure. To predict coatings service lifetime, acceleration tests are necessary. We employ flowing deionized water to accelerate coating degradation. Coating barrier properties are found, via electrochemical impedance spectroscopy (EIS), to decrease as flow rate (Q) increases, similar to findings for coatings in NaCl solution. EIS modulus decreases more for coatings in deionized water than those in electrolyte solution. Topographical characterizations show severe coating blistering in deionized water immersion with higher Q, but not in electrolyte solutions. Deionized water is thus believed to accelerate more aggressively the degradation than electrolyte solution. [Copyright &y& Elsevier]

Published

2012

17. Synthetic scaffolds increased resveratrol biosynthesis in engineered yeast cells

Author

Wang, Yechun and Yu, Oliver

Subjects

*RESVERATROL, *BIOSYNTHESIS, *YEAST, *PHENOLS, *PATHOGENIC microorganisms, *BACTERIA, *SACCHAROMYCES cerevisiae

Abstract

Abstract: Resveratrol is a polyphenolic compound produced by a few higher plants when under attack by pathogens such as bacteria or fungi. Besides antioxidant benefits to humans, this health-promoting compound has been reported to extend longevity in yeasts, flies, worms, fishes and obesity mice. Here we utilized the synthetic scaffolds strategy to improve resveratrol production in Saccharomyces cerevisiae. We observed a 5.0-fold improvement over the non-scaffolded control, and a 2.7-fold increase over the previous reported with fusion protein. This work demonstrated the synthetic scaffolds can be used for the optimization of engineered metabolic pathway. [Copyright &y& Elsevier]

Published

2012

18. Visualization of bubble dynamic behaviors during photoelectrochemical water splitting with TiO2 photoelectrode.

Author

Cao, Zhenshan, Wang, Yechun, Xu, Qiang, Feng, Yuyang, Hu, Xiaowei, and Guo, Liejin

Subjects

*BUBBLES, *PHOTOCATHODES, *VISUALIZATION, *MARANGONI effect

Abstract

Bubble dynamic behaviors from photoelectrochemical water splitting are key issues in the interfacial mass transport on photocatalyst surface. To date, the interaction between gas bubbles and photocatalyst surfaces has received limited attention, especially bubble bouncing behaviors during photoelectrochemical process have rarely been discussed in the literature. In this study, a visualization method by external chopping disturbance was proposed to regulate bubble dynamic behaviors on the TiO 2 photoelectrode surface during photoelectrochemical reaction. Under continuous irradiation, the dominant physics in each bubble growth phase were inertia-controlled, the transition from diffusion-controlled to chemical reaction-controlled and the chemical reaction-controlled. Under rhythmically chopping, the bouncing bubble grew only while in contact with the photoelectrode and its trajectory was approximately to a spiral shape. The proportion of the acceleration stage was very small during the overall rising process, and the bubble rise velocity can be approximately as constant. The main reason for the bubble no longer return is that the rising distance is too far to feel the Marangoni attraction force. • A method to regulate bubble dynamic behaviors by chopping is proposed. • Single bubble evolution is controlled by different dominant physics in each phase. • Bouncing bubbles keep spherical and grow only while in contact with photoelectrode. • The motion trajectory of bouncing bubble is approximately to a spiral shape. • Main reason for no longer return is the bubbles rise too far to feel attraction. [ABSTRACT FROM AUTHOR]

Published

2020

19. Quantitative description of droplet dispersion of hollow cone spray in gaseous crossflow.

Author

Zhang, Haibin, Bai, Bofeng, and Wang, Yechun

Subjects

*CROSS-flow (Aerodynamics), *DISPERSION (Chemistry), *GAS flow, *FLOW visualization, *VORTEX motion, *REYNOLDS number, *HEAT flux

Abstract

In this study, we experimentally investigate the large-scale vortex pair formed by droplets in the spanwise direction of the flow field of a hollow cone spray injected transversely into a gaseous crossflow. Experiments are conducted in a square channel for a wide range of spray and crossflow conditions. The spatial and velocity distributions of the spray droplets for different cross-sections of the flow field in terms of different flow conditions are measured through flow visualization. Three parameters, namely, vortex vorticity, depth of vortex core, and distance between both vortex cores, are used to characterize the counter-rotating vortex pair (CVP) formed by droplets. The crossflow Reynolds number, (initial atomized) droplet Reynolds number, and number of droplets injected per unit time are all found to significantly influence the features of droplets CVP. We newly define the spray-to-crossflow momentum flux ratio ( J ∗) based on the injected momentum flux of initial atomized droplets. Accordingly, we develop a set of correlations for predicting the features of droplets CVP based on experimental measurements and the Buckingham π theorem. The results show that these correlations well predict all measured conditions. The results of this study should provide insights into the dynamics of spray droplets in a crossflow and an understanding of the large-scale mixing between a hollow cone spray and a crossflow. [ABSTRACT FROM AUTHOR]

Published

2018

20. Development of Candle Soot Based Carbon Nanoparticles (CNPs)/Polyaniline Electrode and Its Comparative Study with CNPs/MnO2 in Supercapacitors.

Author

Wang, Yong, Jiang, Long, and Wang, Yechun

Subjects

*POLYANILINES, *ELECTRODES, *SUPERCAPACITORS, *MANGANESE dioxide, *NANOPARTICLES, *CURRENT density (Electromagnetism)

Abstract

In this article we report a facile method to create a polyaniline (PANI) nanorod/carbon nanoparticle (CNP) composite structure that is suitable for supercapacitor use. A network of CNPs was conveniently produced on the surface of a nickel foam by collecting candle soot above a burning candle. The PANI nanorods were then electrochemically deposited on the CNP network, forming a star-like interconnected 3D structure. As a comparison, MnO 2 particles were also deposited on the CNP network to produce a broccoli-like structure. The electrochemical properties of these two composites were examined using cyclic voltammetry, cyclic charge-discharge, and electrochemical impedance spectroscopy. The two electrodes exhibited different electrochemical behaviors: high capacitance at low current densities and marked deterioration at high ones for CNPs/PANI and relatively low but stable capacitance for CNPs/MnO 2 . The reasons for this distinction were discussed based on the structures and material properties of the electrodes. [ABSTRACT FROM AUTHOR]

Published

2016

21. Single Photogenerated Bubble at Gas-Evolving TiO2 Nanorod-Array Electrode.

Author

Hu, Xiaowei, Cao, Zhenshan, Wang, Yechun, Shen, Shaohua, Guo, Liejin, and Chen, Juanwen

Subjects

*TITANIUM dioxide nanoparticles, *BUBBLES, *NANORODS, *PHOTOELECTROCHEMISTRY, *ELECTRODES, *HYDROPHILIC interactions

Abstract

This paper presents a study on single bubble photogenerated by 376 nm laser light at TiO 2 nanorod-array electrode during photoelectrochemical (PEC) conversion. The surface properties of TiO 2 nanorod-array electrode were investigated at first for a better understanding of the three-phase contact line behavior. The results indicate the light-induced hydrophilic effect of TiO 2 nanorod-array electrode under illumination, which makes bubble tend to be pseudo-sphere shape during attaching on electrode. The experimental investigation on photogenerated bubble at TiO 2 nanorod-array electrode shows that there is a linear relationship between cubic root of time and bubble radius, demonstrating the gas products from the surface reaction transferring into bubble through bubble bottom according to the analysis of the relative size between bubble and effective solid surface. Furthermore, the coupling effects between bubble and irradiance were discussed. The bubble scatter effect on light causes a local light intensity increase at electrode surface area on both sides of bubble, and leads to photocurrent increase especially at small bubble size. While the increase of irradiance causes the parameters of bubble evolution period, dissolved gas concentration for nucleation and departure diameter increase, but leads to bubble evolution rate and incident photon conversion efficiency (IPCE) decrease. These results suggest a lower irradiance is preferred for a higher PEC conversion efficiency from the aspects of IPCE and bubble evolution rate. [ABSTRACT FROM AUTHOR]

Published

2016

22. Prediction of hydrodynamic and optical properties of TiO2/water suspension considering particle size distribution.

Author

Song, Dongxing, Hatami, Mohammad, Wang, Yechun, Jing, Dengwei, and Yang, Yang

Subjects

*OPTICAL properties of titanium dioxide, *HYDRODYNAMICS, *NATURAL heat convection, *PARTICLE size distribution, *WIENER processes, *SCANNING electron microscopes

Abstract

In this study, evolution and final state of particle size distribution (PSD) of TiO 2 /water suspension were described by a modified population balance equation considering both natural convection and Brownian motion. The calculation was verified by experimental measurement of scanning electron microscope and Laser particle analyzer. Based on the predicted PSD, Rayleigh scattering theory (for d < 4 λ ) and Fraunhofer diffraction theory (for d > 4 λ ) were then employed to determine the scattering and absorption coefficients of TiO 2 /water suspensions with various particle concentrations and at various light wavelengths. UV–Vis investigation showed that the predicted optical properties of TiO 2 /water suspension considering PSD are in much better agreement with the experimental results than that without considering PSD, at all particle concentrations investigated. It is traditionally accepted that for colloid suspension the scattering coefficient can be neglected compared to the absorption coefficient and therefore the extinction, which is the combination of the absorption and scattering coefficients, can be approximately replaced by the absorption coefficient. However, our finding indicates that, when particle aggregation is considered, the scattering coefficient of TiO 2 /water suspension could be much higher than the absorption coefficient. Consequently, using the absorption coefficient alone to replace the extinction coefficient even at long wavelengths could result in significant calculation errors and is not recommended. [ABSTRACT FROM AUTHOR]

Published

2016

23. Experiments and predictions for severe slugging of gas-liquid two-phase flows in a long-distance pipeline-riser system.

Author

Chang, Yingjie, Xu, Qiang, Zou, Suifeng, Zhao, Xiangyuan, Wu, Quanhong, Wang, Yechun, Thévenin, Dominique, and Guo, Liejin

Subjects

*TWO-phase flow, *ELECTRICAL capacitance tomography, *RISER pipe, *POROSITY

Abstract

Experiments concerning the flow regimes observed in gas-liquid two-phase flows in a long-distance pipeline-riser system were carried out and analyzed in this paper. The test loop with 0.075 m inner diameter consisted of a 314 m horizontal pipeline, followed by a 25 m downward-inclined pipe, and finally a 21.5 m riser pipe. An industrial-scale global flow regime map including 5 flow regimes was derived from differential pressure measurements in the riser and was used as a reference for improvements. Electrical capacitance volume tomography installed in the horizontal section was used to reconstruct the phase interface and calculate the average gas void fraction (GVF). An appropriate model for this system was selected by comparing the experimental GVF with different, widely used models. The occurrence of severe slugging flow (SS) can be predicted accurately using an improved model involving additional corrections that consider pipeline length, accurate GVF calculation, and gas density. This study supports the development of a suitable SS prediction model enabling safe design, operation, and control of practical systems. • The phase interface was reconstructed by ECVT to obtain gas void fraction (GVF). • Experiments on gas-liquid two-phase flow in an industrial-scale system were conducted. • Effect of pipeline length/GVF/gas density on severe slugging was analyzed. • An improved model to predict occurrence of severe slugging was derived. [ABSTRACT FROM AUTHOR]

Published

2024

24. Periodical oscillation of particle-laden laminar flow within a tubular photocatalytic hydrogen production reactor predicted by discrete element method.

Author

Geng, Jiafeng, Tang, Junwang, Cai, Wenfang, Wang, Yechun, Jing, Dengwei, and Guo, Liejin

Subjects

*LAMINAR flow, *HYDROGEN production, *DISCRETE element method, *PARTICLE size distribution, *OSCILLATIONS, *PERIODICAL circulation

Abstract

Besides their wide existence in various industrial processes, nanoscale particle suspensions are also the important media for some emerging technologies such as photocatalytic hydrogen production. The circulating flow properties of the nanoparticles in the fluid are of great concern for their practical use. In our study, a modified experimental system was set up based on Malvern laser particle analyzer that can estimate the nanoparticle concentration and size distribution in a laminar nanoparticle circulating flow. We found that the particle concentration and size distribution were periodical oscillation with time in such flow. Understanding the oscillation mechanism is capable of promote the energy efficiency of photocatalytic hydrogen production. A simulation based on Discrete Element Method (DEM) was conducted to understand this particular oscillation mechanism by studying the single particle movement and trajectory properties in the solid-liquid suspension. The simulation results agree well with the tendency obtained by the experimental results and are capable of better understanding the oscillation characteristics. The simulation results also reveal that the nanoparticles tend to gather in the middle region (the higher velocity region) of the tube after several cycles. Moreover the gravity is of great significance in the circulating flow of solid-liquid suspension because the particle swarms tend to distribute a little below the axial center line of the straight tube. These obtained results are credible for understanding the nanoscale particle transport phenomenon in many natural or industrial processes. In particular, our results are helpful for the understanding and effective control of the movement and distribution of photocatalyst particles in the tubular photocatalytic reactor, which is believed to significantly affect the incident radiation distribution and finally the energy conversion efficiency of the photocatalytic process. • A simulation based on DEM method is conducted to predict the particles transport; • A periodical oscillation of the particles volume fraction and size is predicted; • The trajectory and behaviour of single particle was studied by the simulation; • This simulation can be extended to other applications of particulate system. [ABSTRACT FROM AUTHOR]

Published

2021

25. Functionality and structure of yellow pea protein isolate as affected by cultivars and extraction pH.

Author

Cui, Leqi, Bandillo, Nonoy, Wang, Yechun, Ohm, Jae-Bom, Chen, Bingcan, and Rao, Jiajia

Subjects

*POLYACRYLAMIDE gel electrophoresis, *PEAS, *FOURIER transform infrared spectroscopy, *SODIUM dodecyl sulfate, *GEL permeation chromatography, *SULFHYDRYL group

Abstract

Pea (Pisum sativum L.) has been a promising source of plant-based protein, but better protein functionalities are needed by the food industry. In this study, pea protein isolate (PPI) was extracted by alkaline extraction-isoelectric precipitation method, followed by spray-drying. The functional attributes of PPI, as affected by four different cultivars (Agassiz, Spider, Trapeze and ND Trial) and four alkaline extraction pH (8.5, 9.0, 9.5, 10.0), were firstly studied. Results showed that cultivars had significant impacts on the solubility, emulsifying capacity and stability, and foaming capacity and stability of PPI, while alkaline extraction pH only affected emulsifying stability, and foaming capacity and stability. The protein structural characteristics were then evaluated using sodium dodecyl sulfate polyacrylamide gel electrophoresis, size exclusion chromatography with multi-angle static light scattering, quantification of sulfhydryl/disulfide group and Fourier transform infrared spectroscopy analyses. The contents of legumin, aggregates, exposed sulfhydryl group and β-turn structure were different among PPI of different cultivars. Additionally, increasing alkaline extraction pH from 8.5 to 10.0 resulted in PPI with reduced surface tension, which contributed to their better foaming capacity and stability. Image 1 • Pea protein isolates (PPI) from different cultivars differed in functionality. • The structure and composition of PPI were different among cultivars. • The lower legumin/vicilin ratio, the better functionality of PPI. • PPI prepared by higher alkaline extraction pH had better foaming properties. [ABSTRACT FROM AUTHOR]

Published

2020

26. Biosynthesis of terpene compounds using the non-model yeast Yarrowia lipolytica: grand challenges and a few perspectives.

Author

Worland, Alyssa M, Czajka, Jeffrey J, Li, Yanran, Wang, Yechun, Tang, Yinjie J, and Su, Wei Wen

Subjects

*BIOSYNTHESIS, *TERPENES, *PROTEIN engineering, *YEAST, *KNOWLEDGE gap theory, *FERMENTATION products industry, *ACETYLCOENZYME A

Abstract

• Yarrowia has shown the potential for producing complex terpenoids. • Yarrowia may hold multiple cytosolic acetyl-CoA and NADPH generation pathways. • Metabolite channeling is a key consideration in terpene pathway engineering. • Knowledge gaps exist in compartment-specific fluxes for utilizing alternative carbon sources (e.g., lipids). • Metabolic shift, genetic stability, and dimorphism in large-scale Yarrowia fermentation need further studies. Yarrowia lipolytica has emerged as an important non-model host for terpene production. However, three main challenges remain in industrial production using this yeast. First, considerable knowledge gaps exist in metabolic flux across multiple compartments, cofactor generation, and catabolism of non-sugar carbon sources. Second, many enzymatic steps in the complex-terpene synthesis pathway can pose rate-limitations, causing accumulation of toxic intermediates and increased metabolic burdens. Third, metabolic shifts, morphological changes, and genetic mutations are poorly characterized under industrial fermentation conditions. To overcome these challenges, systems metabolic analysis, protein engineering, novel pathway engineering, model-guided strain design, and fermentation optimization have been attempted with some successes. Further developments that address these challenges are needed to advance the Yarrowia lipolytica platform for industrial-scale production of high-value terpenes, including those with highly complex structures such as anticancer molecules withanolides and insecticidal limonoids. [ABSTRACT FROM AUTHOR]

Published

2020

27. An improved void fraction prediction model for gas-liquid two-phase flows in pipeline-riser systems.

Author

Chang, Yingjie, Xu, Qiang, Zou, Suifeng, Zhao, Xiangyuan, Wu, Quanhong, Wang, Yechun, Thévenin, Dominique, and Guo, Liejin

Subjects

*TWO-phase flow, *POROSITY, *ELECTRICAL capacitance tomography, *PREDICTION models, *STANDARD deviations, *STRATIFIED flow

Abstract

• The phase interface in the upstream horizontal section was reconstructed using ECVT. • Upstream interface drop and slugging are induced by the flow in the riser. • Lockhart-Martinelli model is found to be best and is used for improved correlation. • An improved void fraction prediction model is proposed for pipeline-riser systems. • This improved model leads to considerably reduced prediction errors. This paper introduces the application of void fraction prediction models (25 models total) from a simple horizontal pipe to a complex, real pipeline. The flow mechanism in the pipeline-riser system is explained based on the upstream phase interface and differential pressure in the downstream riser. The transition boundaries of "stratified to intermittent flow" and "stratified smooth to stratified wavy flow" in the horizontal section were predicted well by the models based on simple pipes. Electrical capacitance volume tomography was used to obtain the upstream void fraction just before the downstream gas-liquid eruption, α 1 , or during multiple cycles, α 2. The difference between α 1 and α 2 are ranging between −10 % and 5 %. Finally, an improved correlation is proposed based on the model found to be best (Lockhart and Martinelli, with error values (root mean square error (RMSE) and mean absolute percentage error (MAPE)) of about 12 % and 18 %); the corresponding error levels (RMSE and MAPE) amount roughly to 5 % and 10 %, respectively. The improved model also delivers a good prediction for α 1 when separating in two flow regimes. Overall, the finally proposed correlation reads and is found superior in terms of accuracy to all previously published correlations. [ABSTRACT FROM AUTHOR]

Published

2023

28. Dynamics of single bubble departure from TiO2 nanorod-array photoelectrode.

Author

Chen, Juanwen, Guo, Liejin, Hu, Xiaowei, Cao, Zhenshan, and Wang, Yechun

Subjects

*BUBBLE dynamics, *TITANIUM dioxide, *NANORODS, *WATER electrolysis, *OXIDE electrodes

Abstract

Bubble evolution from photo(electro)catalytic water splitting plays a vital role in the interfacial mass transport on photocatalyst surface. However, little success has been achieved to optimize this process, restricted by the poor understanding. Herein, taking photoelectrochemical (PEC) water splitting over a titanium dioxide (TiO 2 ) nanorod-array electrode as a model system, experiments were performed to study single oxygen bubble dynamics by combining electrochemical measurement and high-speed microscopic imaging. The experimental results indicate that the departure of bubble from photoelectrode is retarded by light irradiation, but the traditional bubble departure criterions fail to predict the bubble departure diameters especially in high light intensity. Additional analysis reveals that the light irradiation causes the Marangoni force acting on the evolving bubble, because it induces temperature rise and generates dissolved gas. A modified force balance model for bubble departure from photoelectrode was developed by adding Marangoni force. This modified model that takes account of the light-induced temperature rise and the dissolved gas, agrees well with the experimental data and can be extended to other photo(electro)catalytic reactions. [ABSTRACT FROM AUTHOR]

Published

2018

29. Experimental investigation of enhanced oil recovery and in-situ upgrading of heavy oil via CO2- and N2-assisted supercritical water flooding.

Author

Huang, Zujie, Zhao, Qiuyang, Chen, Lei, Guo, Liejin, Miao, Yan, Wang, Yechun, and Jin, Hui

Subjects

*HEAVY oil, *SUPERCRITICAL water, *ENHANCED oil recovery, *PETROLEUM in submerged lands, *TECHNOLOGICAL innovations, *CARBON dioxide, *ENERGY shortages

Abstract

• SCW/CO 2 /N 2 mixture injection is proposed for heavy oil recovery. • A core experimental system of SCW/CO 2 /N 2 flooding is developed. • SCW/CO 2 /N 2 flooding is divided into three stages. • CO 2 and N 2 provide the driving force and eliminate gravity override. • SCW/CO 2 /N 2 flooding can both enhance oil recovery and upgrade oil quality. Exploitation of heavy oil is critical for mitigating the energy crisis. However, conventional thermal recovery methods cannot completely exploit the potential of heavy oil owing to its high viscosity and heavy distillates. A new technology is proposed with reference to CO 2 – and N 2 -assisted supercritical water (MGA-SCW) injection for heavy oil recovery. In this study, an experimental apparatus was developed to simulate the MGA-SCW flooding process and test its feasibility. MGA-SCW injection remarkably enhanced oil recovery, increased the oil production rate, and improved the oil quality. For MGA-SCW flooding at 25 MPa and 400 °C, the recovery factor approached 95 %, and the oil viscosity decreased by 32 %; the light distillate fraction (180–350 °C) increased from 11 to 15 %. The dynamic process of MGA-SCW flooding is divided into three stages: pressure difference, thermal, and miscible drives. This technology can be applied to the development and utilization of offshore heavy oil fields. [ABSTRACT FROM AUTHOR]

Published

2023

30. Velocity field characteristics of the turbulent jet induced by direct contact condensation of steam jet in crossflow of water in a vertical pipe.

Author

Xu, Qiang, Guo, Liejin, Chang, Liang, and Wang, Yechun

Subjects

*TURBULENT jets (Fluid dynamics), *DIRECT contact heat exchanger, *CONDENSATION, *STEAM jets, *CROSS-flow (Aerodynamics), *INDUSTRIAL applications

Abstract

Direct contact condensation of jets in fluid has been widely applied in many industrial applications owing to the low requirement of driving potential and high efficiency of heat and mass transfer. Here, experiments are carried out to investigate the velocity field characteristics of the turbulent jet induced by direct contact condensation of steam jet in crossflow of water in a vertical pipe. Visual equipment is specially invented to investigate the velocity field characteristics by using Particle Image Velocimetry (PIV) measurement technique. The high intensity laser light reflected by the pure steam region just outside the nozzle-exit brings out severe damage to the CCD camera. To solve this technical problem, a black plate is adopted to shield the pure steam region. According to the contours of the velocity fields and streamlines, the influences of jet momentum ratio, jet Reynolds number and water temperature on the jet flow field are explored. The jet centerline trajectory equations in exponential form are established based on the local maximum mean velocity. By introducing the jet Reynolds number and jet momentum ratio, the correlation for prediction of jet centerline trajectory equations is proposed, and the predicted results are within 30% of the experimental data. The reciprocal of the local maximum mean velocity and the half-width of the jet are proportional to the downstream coordinate along the jet velocity centerline trajectory. The scaled velocity field complies with the self-similarity principle. [ABSTRACT FROM AUTHOR]

Published

2016

31. Mass transfer mechanism during bubble evolution on the surface of photoelectrode.

Author

Cao, Zhenshan, Zhang, Bo, Feng, Yuyang, Xu, Qiang, Wang, Yechun, and Guo, Liejin

Subjects

*MASS transfer, *MASS transfer coefficients, *FREE convection, *NATURAL heat convection, *WATER efficiency, *TITANIUM dioxide

Abstract

• An expression for single bubble coverage on the photoelectrode surface is proposed. • The mass transfer is dominated by single-phase free convection in low current density. • The mass transfer coefficient peaks in the inertia-controlled bubble growth phase. • Periodic illumination accelerates bubble detachment and enhances mass transfer. The limitation of the transfer of gas products within the photocatalytic system is the key to the efficiency of the water splitting, which is directly influenced by the bubble evolution process on the catalyst surface. In this study, the entire process of bubble evolution on the surface of a superhydrophilic TiO 2 photoelectrode was simultaneously measured visually and electrochemically. The bubble growth and detachment characteristics were investigated under different laser powers and constant bias voltages. An expression for the bubble coverage characterized by the bubble radius and photocurrent, which is applicable to the photoelectrocatalytic water splitting, was proposed to accurately obtain the mass transfer coefficient during bubble evolution. The mass transfer mechanism of gas product transfer in the low current density range dominated by single-phase free convection was revealed. The mass transfer coefficient was found to increase in the inertia-controlled phase and decrease in the chemical reaction-controlled phase of bubble growth. Furthermore, a method to accelerate bubble detachment from the photoelectrode surface by periodic illumination was proposed, which could significantly enhance the gas product transfer process. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

32. Experimental study of the hydraulic jump phenomenon induced by the downstream riser structure in a pipeline–riser system.

Author

Chang, Yingjie, Xu, Qiang, Wu, Quanhong, Zhao, Xiangyuan, Huang, Bo, Wang, Yechun, and Guo, Liejin

Subjects

*RISER pipe, *HYDRAULIC jump, *ELECTRICAL capacitance tomography, *TRANSITION flow, *TWO-phase flow, *PEARSON correlation (Statistics)

Abstract

• The interface wave in the horizontal section before the riser was studied by an ECVT. • Flow regime transition boundaries shift to lower velocities due to the riser. • The period of hydraulic jump is consistent with that of severe slugging flow. • The hydraulic jump upstream is mainly caused by pressure fluctuations of the riser. This paper describes experiments conducted on the gas–liquid two-phase flow characteristics in a pipeline-riser system under 1 MPa. The hydraulic jump phenomenon (HJP) in the upstream horizontal section was quantitatively studied using electrical capacitance volume tomography (ECVT). Flow regime transition boundaries were shifted to lower gas and liquid velocities due to the impact of the riser at the end of the horizontal pipe. The HJP's period is consistent with that of severe slugging flow; additionally, the liquid slug production and the gas–liquid eruption stages always occur before the HJP in the upstream horizontal section. The Pearson correlation coefficient between the HJP upstream and the pressure fluctuations in the three main structures (horizontal, downward, and riser sections), the period consistency, and the sequential relationship between them were analyzed to verify that the pressure fluctuations in the downstream riser were the main cause of the HJP upstream. [ABSTRACT FROM AUTHOR]

Published

2022

33. Oriented thermal etching of hollow carbon spheres with delicate heat management for efficient solar steam generation.

Author

Tan, Yubo, Liu, Maochang, Wei, Daixing, Ren, Jun, Wang, Yechun, Jin, Hui, and Shen, Shaohua

Subjects

*SOLAR energy conversion, *PHOTOTHERMAL conversion, *SOLAR thermal energy, *SPHERES, *HEAT radiation & absorption, *ETCHING

Abstract

• Monodispersed HCSs with tunable cavity size were synthesized through a thermal-etching process without template. • The "inside-out" oriented thermal etching process was induced by the "core-shell" differentiated chemical structures of CSs. • HCSs exhibited a SISG efficiency as high as 88.9%, which outperforms most of the previously reported carbon-based materials. • The delicate heat management contributes to the significantly improved SISG efficiency. Hollow carbon spheres (HCSs) with controllable morphology and structure have received considerable attention in the field of energy conversion and storage. Herein, monodispersed HCSs with cavity sizes tuned from 100 nm to 800 nm and shell thickness from 450 nm to 50 nm were successfully synthesized through a unique template-free thermal-etching method. It was evidenced that the dynamically controllable synthesis of HCSs was attributed to the "inside-out" oriented thermal oxidation etching of carbon spheres (CSs) induced by the differentiated "core-shell" chemical structures. Comparing to CSs, the obtained HCSs exhibited much increased efficiency for solar-driven interfacial steam generation (SISG), reaching as high as 88.9%, which outperforms most of the previously reported carbon-based materials. It was then demonstrated that the rational heat management for both photothermal and thermal-evaporation conversion is essential to achieve satisfying SISG efficiency. Depending on the increasing cavity sizes, HCSs presented gradual increases in both photothermal conversion and thermal-evaporation performances, mainly attributed to the improved light absorption and the delicate heat management, respectively. However, the further increase in cavity size resulted in excessive heat loss and presented decreased thermal-evaporation performance. This work provides an alternative and promising approach to the reasonable design of hollow nanostructures with delicate heat management for efficient SISG as well as other solar energy conversion applications. Hollow carbon spheres with tunable cavity was synthesized by an oriented thermal etching of hydrothermally synthesized carbon spheres, which exhibited excellent solar steam generation performances, with delicate heat management in both photothermal conversion and thermal-evaporation processes. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2021

34. Molecular cloning, expression profiling and functional analysis of a DXR gene encoding 1-deoxy-d-xylulose 5-phosphate reductoisomerase from Camptotheca acuminata

Author

Yao, Hongyan, Gong, Yifu, Zuo, Kaijing, Ling, Hua, Qiu, Chengxiang, Zhang, Fei, Wang, Yechun, Pi, Yan, Liu, Xiang, Sun, Xiaofen, and Tang, Kexuan

Subjects

*RESEARCH, *GENETIC engineering, *MOLECULAR cloning, *BIOSYNTHESIS

Abstract

Summary: As the second enzyme of the non-mevalonate terpenoid pathway for isopentenyl diphosphate biosynthesis, DXP reductoisomerase (DXR, EC: 1.1.1.267) catalyzes a committed step of the MEP pathway for camptothecin (CPT) biosynthesis. In order to understand more about the role of DXR involved in the CPT biosynthesis at the molecular level, the full-length DXR cDNA sequence (designated as CaDXR) was isolated and characterized for the first time from a medicinal Nyssaceae plant species, Camptotheca acuminata. The full-length cDNA of CaDXR was 1823bp containing a 1416bp open reading frame (ORF) encoding a polypeptide of 472 amino acids. Comparative and bioinformatic analyses revealed that CaDXR showed extensive homology with DXRs from other plant species and contained a conserved transit peptide for plastids, an extended Pro-rich region and a highly conserved NADPH binding motif in its N-terminal region owned by all plant DXRs. Phylogenetic analysis indicated that CaDXR was more ancient than other plant DXRs. Tissue expression pattern analysis revealed that CaDXR expressed strongly in stem, weak in leaf and root. CaDXR was found to be an elicitor-responsive gene, which could be induced by exogenous elicitor of methyl jasmonate. The functional color complementation assay indicated that CaDXR could accelerate the biosynthesis of carotenoids in the Escherichia coli transformant, demonstrating that DXP reductoisomerase plays an influential step in isoprenoid biosynthesis. [Copyright &y& Elsevier]

Published

2008